Stem cell protein BMI-1 is an independent marker for poor prognosis in oligodendroglial tumours.

AIMS: The polycomb factor BMI-1 has recently been implicated in tumorigenesis of the central nervous system in several experimental animal models. However, the significance of BMI-1 in human glioma has not been investigated. Here we describe expression of the polycomb protein BMI-1 and its downstream targets p16(Ink4a) and MDM2 in both high- and low-grade human glioma. METHODS: Tumour samples were collected from 305 adult patients treated for primary grades 2-4 gliomas between 1980 and 2006 in Finland and Germany. BMI-1, p16 and MDM2 expression was evaluated using immunohistochemistry in representative paraffin-embedded tumour tissue. The significance of observed immunoreactivity, age at onset, gender, histopathological findings and proliferative index was analysed in univariate and multivariate survival models. RESULTS: BMI-1 was expressed in all histologic types of diffuse gliomas. We found a significant correlation (P = 0.007) between the frequency of BMI-1 immunoreactive tumour cells and poor survival in World Health Organization grades II-III oligodendrogliomas and oligoastrocytomas (n = 62). The median survival of patients grouped by low, intermediate or high frequency of BMI-1 immunoreactive tumour cells was 191 months, 151 months and 68 months, respectively. This association was also significant in the Cox multivariate regression model. Nuclear p16 immunopositivity predicted better survival in astrocytomas and an inverse correlation between p16 expression and the Ki-67 mitotic index was also observed. CONCLUSIONS: BMI-1 is found in all histological types of gliomas and the relative protein expression of BMI-1 is a novel independent prognostic marker in oligodendroglial tumours.

Gene expression signatures for colorectal cancer microsatellite status and HNPCC.

The majority of microsatellite instable (MSI) colorectal cancers are sporadic, but a subset belongs to the syndrome hereditary non-polyposis colorectal cancer (HNPCC). Microsatellite instability is caused by dysfunction of the mismatch repair (MMR) system that leads to a mutator phenotype, and MSI is correlated to prognosis and response to chemotherapy. Gene expression signatures as predictive markers are being developed for many cancers, and the identification of a signature for MMR deficiency would be of interest both clinically and biologically. To address this issue, we profiled the gene expression of 101 stage II and III colorectal cancers (34 MSI, 67 microsatellite stable (MSS)) using high-density oligonucleotide microarrays. From these data, we constructed a nine-gene signature capable of separating the mismatch repair proficient and deficient tumours. Subsequently, we demonstrated the robustness of the signature by transferring it to a real-time RT-PCR platform. Using this platform, the signature was validated on an independent test set consisting of 47 tumours (10 MSI, 37 MSS), of which 45 were correctly classified. In a second step, we constructed a signature capable of separating MMR-deficient tumours into sporadic MSI and HNPCC cases, and validated this by a mathematical cross-validation approach. The demonstration that this two-step classification approach can identify MSI as well as HNPCC cases merits further gene expression studies to identify prognostic signatures.

Genetic alterations and protein expression of KIT and PDGFRA in serous ovarian carcinoma.

KIT and PDGFRA are receptor tyrosine kinases that can be specifically inactivated by small-molecule tyrosine kinase inhibitors, notably imatinib mesylate. In ovarian carcinoma, expression of KIT and PDGFRA protein has been documented, but the frequency and the molecular background of expression are poorly known. We analysed the expression of KIT and PDGFRA by immunohistochemistry in 522 serous ovarian carcinomas, and mutations of KIT and PDGFRA by denaturing high-performance liquid chromatographyin 125 and 187 serous ovarian carcinomas, respectively. No mutations of KIT or PDGFRA were detected. KIT expression was detected in 12% of carcinomas: low expression in 10% and high expression in 2% of cases. Using normal serous epithelium as a reference, decreased PDGFRA expression was detected in 12% and increased expression in 13% of carcinomas. Both KIT and PDGFRA expression were associated with high tumour grade, high proliferation index and poor patient outcome. By fluorescence in situ hybridisation, no KIT amplification was found in carcinomas with high KIT expression, but two cases showed a relative gain of chromosome 4. In conclusion, no mutations of KIT or PDGFRA were found, but a subset of serous ovarian carcinoma showed overexpression of the proteins, which was associated with aggressive tumour characteristics.

Amplification of EIF3S3 gene is associated with advanced stage in prostate cancer.

Gain of the long arm of chromosome 8 (8q) is one of the most common gains found in the advanced prostate cancer by comparative genomic hybridization. We have previously identified a putative target gene for the 8q gain, EIF3S3, that encodes a p40 subunit of eukaryotic translation initiation factor 3 (eIF3). Here, we studied the frequency of the EIF3S3 amplification in different stages of prostate cancer and co-amplification of EIF3S3 and oncogene MYC. In addition, prognostic utility of the EIF3S3 copy number alteration was evaluated. The analyses were done with fluorescence in situ hybridization and tissue microarray technology. High-level amplification of EIF3S3 was found in 11 of 125 (9%) of pT1/pT2 tumors, 12 of 44 (27%) of pT3/pT4 tumors, and 8 of 37 (22%) of lymph node metastases as well as in 26 of 78 (33%) and 15 of 30 (50%) of hormone refractory locally recurrent tumors and metastases, respectively. The amplification was associated with high Gleason score (P < 0.001). One of the 79 tumors with EIF3S3 amplification had only two copies of MYC, whereas all tumors with amplification of MYC had also amplification of EIF3S3 indicating common co-amplification of the genes. Gain of EIF3S3 was associated with poor cancer-specific survival in incidentally found prostate carcinomas (P = 0.023). In the analyses of prostatectomy-treated patients, the amplification was not statistically significantly associated with progression-free time. In conclusion, amplification of EIF3S3 gene is common in late-stage prostate cancer suggesting that it may be functionally involved in the progression of the disease.

Gastrointestinal stromal tumors with KIT mutations exhibit a remarkably homogeneous gene expression profile.

Gastrointestinal stromal tumors (GISTs), the most common mesenchymal tumors of the digestive tract, are believed to arise from the interstitial cells of Cajal. GISTs are characterized by mutations in the proto-oncogene KIT that lead to constitutive activation of its tyrosine kinase activity. The tyrosine kinase inhibitor STI571, active against the BCR-ABL fusion protein in chronic myeloid leukemia, was recently shown to be highly effective in GISTs. We used 13,826-element cDNA microarrays to define the expression patterns of 13 KIT mutation-positive GISTs and compared them with the expression profiles of a group of spindle cell tumors from locations outside the gastrointestinal tract. Our results showed a remarkably distinct and uniform expression profile for all of the GISTs. In particular, hierarchical clustering of a subset of 113 cDNAs placed all of the GIST samples into one branch, with a Pearson correlation >0.91. This homogeneity suggests that the molecular pathogenesis of a GIST results from expansion of a clone that has acquired an activating mutation in KIT without the extreme genetic instability found in the common epithelial cancers. The results provide insight into the histogenesis of GIST and the clinical behavior of this therapeutically responsive tumor.

Amplification of hypoxia-inducible factor 1alpha gene in prostate cancer.

Hypoxia-inducible factor 1 (HIF-1) is a transcription factor that regulates the expression of genes associated with adaptation to reduced oxygen pressure. Increased expression of HIF-1alpha gene (HIF1A) has been found in the majority of prostate carcinomas. In addition, the PC-3 prostate cancer cell line has been shown to express the gene even under normoxic conditions. By comparative genomic hybridization (CGH), we have earlier shown that the PC-3 cell line contains a high-level amplification in the chromosomal region harboring the HIF1A gene. Here, we first fine mapped the gene to locus 14q23 by fluorescence in situ hybridization (FISH). The gene was then shown to be highly amplified in the PC-3 cell line. Subsequently, the copy number of the HIF1A gene was studied in 5 other prostate cancer cell lines (LNCaP, DU-145, NCI-H660, Tsu-Pr, JCA-1) and in 117 prostate tumors representing both hormone-dependent and -refractory disease as well as primary and metastatic lesions. No high-level amplifications of the HIF1A gene were found. Additional copies of the gene were seen in all of the cell lines and in 36% of the tumors. There was no association between the tumor type and the copy number alterations of the gene. In conclusion, high-level amplification of the HIF1A gene may explain the overexpression of the gene in the PC-3 prostate cancer cell line. However, such high-level amplification seems to be very rare in prostate cancer.

Evaluation of linkage and association of HPC2/ELAC2 in patients with familial or sporadic prostate cancer.

To investigate the relationship between HPC2/ELAC2 and prostate cancer risk, we performed the following analyses: (1) a linkage study of six markers in and around the HPC2/ELAC2 gene at 17p11 in 159 pedigrees with hereditary prostate cancer (HPC); (2) a mutation-screening analysis of all coding exons of the gene in 93 probands with HPC; (3) family-based and population-based association study of common HPC2/ELAC2 missense variants in 159 probands with HPC, 249 patients with sporadic prostate cancer, and 222 unaffected male control subjects. No evidence for linkage was found in the total sample, nor in any subset of pedigrees based on characteristics that included age at onset, number of affected members, male-to-male disease transmission, or race. Furthermore, only the two previously reported missense changes (Ser217Leu and Ala541Thr) were identified by mutational analysis of all HPC2/ELAC exons in 93 probands with HPC. In association analyses, family-based tests did not reveal excess transmission of the Leu217 and/or Thr541 alleles to affected offspring, and population-based tests failed to reveal any statistically significant difference in the allele frequencies of the two polymorphisms between patients with prostate cancer and control subjects. The results of this study lead us to reject the three alternative hypotheses of (1) a highly penetrant, major prostate cancer-susceptibility gene at 17p11, (2) the allelic variants Leu217 or Thr541 of HPC2/ELAC2 as high-penetrance mutations, and (3) the variants Leu217 or Thr541 as low-penetrance, risk-modifying alleles. However, we did observe a trend of higher Leu217 homozygous carrier rates in patients than in control subjects. Considering the impact of genetic heterogeneity, phenocopies, and incomplete penetrance on the linkage and association studies of prostate cancer and on the power to detect linkage and association in our study sample, our results cannot rule out the possibility of a highly penetrant prostate cancer gene at this locus that only segregates in a small number of pedigrees. Nor can we rule out a prostate cancer-modifier gene that confers a lower-than-reported risk. Additional larger studies are needed to more fully evaluate the role of this gene in prostate cancer risk.

Prostate cancer susceptibility genes: many studies, many results, no answers.

Since the first report of a genome-wide scan for hereditary prostate cancer (HPCA hereinafter) in 1996, several publications have presented data implicating various chromosomal regions by linkage analysis without any consequential identifications of the target genes. The most intensive attention has been focused on chromosome 1, and it has been proposed to contain at least three sub-chromosomal regions (HPC1, PCAP, CAPB) harboring putative prostate cancer susceptibility genes. Nevertheless, one susceptibility gene, ELAC2/HPC2 at chromosome 17, has now been identified. Yet it seems to have a questionable role in prostate cancer predisposition. HPCA susceptibility loci have become undeniable archenemies of prostate cancer investigators, as the results of candidate gene analyses have been bewilderingly inconclusive. Predisposition to prostate cancer is most likely to be caused by several genes, different models of Mendelian inheritance, incomplete penetrance and varying population ethnicity frequencies. We will review the current state of the HPCA field and discuss the difficulties associated with identifying prostate cancer susceptibility genes.

Molecular cytogenetics of prostate cancer.

Prostate cancer is the most common malignancy among men in Western industrialized countries. The molecular pathogenesis of the disease is poorly known. Over the past 10 years, chromosomal aberrations in prostate cancer have been studied with several techniques, such as loss of heterozygosity (LOH), classical cytogenetics, and molecular cytogenetics, namely with fluorescence in situ hybridization (FISH) and comparative genomic hybridization (CGH). These analyses, especially those performed by CGH, have enabled the distinction of the predominant chromosomal regions of involvement in prostate cancer. Studies have shown that the most common chromosomal alterations in prostate cancer are losses at 1p, 6q, 8p, 10q, 13q, 16q, and 18q and gains at 1q, 2p, 7, 8q, 18q, and Xq. Fluorescence in situ hybridization (FISH) has been used to identify the target genes for some of these chromosomal alterations. For example, amplifications of AR (at Xq12), MYC (8q24), and EIF3S3 (8q23) have been found in a large fraction of hormone-refractory prostate cancer by FISH. However, many of the critical oncogenes and tumor suppressor genes located in the altered chromosomal regions have not yet been identified.

Multiple copies of mutant BRCA1 and BRCA2 alleles in breast tumors from germ-line mutation carriers.

Inactivation of the BRCA1 and BRCA2 breast cancer susceptibility genes has been reported to occur via a germ-line mutation of one allele and a somatic loss of the remaining wild-type allele. We investigated the genetic mechanisms behind the second event in breast tumors from 17 BRCA1 and eight BRCA2 germ-line mutation carriers, as compared with 21 sporadic breast tumors. Microsatellite markers intragenic or in close proximity to both genes were used to analyze imbalances between the mutant and wild-type alleles. The actual and relative gene copy numbers were scored by fluorescence in situ hybridization (FISH) analysis of tumor cells using locus and centromere specific probes. All but one of the informative BRCA1 and BRCA2 tumors exhibited allelic imbalance and loss of the corresponding wild type allele. In contrast to sporadic tumors, however, where allelic imbalance at the BRCA1 and BRCA2 loci correlated well with relative copy number losses by FISH, a simple reduction to a single copy (average copy number ratio 2:1) was found in only two BRCA1 (12%) and four BRCA2 (50%) tumors. The majority of BRCA1 and BRCA2 tumors showed a copy number reduction (relative to reference probe with ratios 4:2, 3:2, 4:3) at corresponding loci, suggesting that a specific physical deletion of the wild-type BRCA gene allele has been followed by a duplication of the remaining mutant allele via polyploidization. Several tumors contained multiple copies of BRCA1 and BRCA2 genes without relative copy number changes, implying that loss of wild-type alleles is executed by alternative mechanisms such as mitotic recombination, non-disjunctional chromosomal loss with or without reduplication, or by gene conversion. A paradoxical relative copy number gain of the mutant allele was evident in three BRCA1 tumors (18%), which could be of biological relevance if a dominant negative or gain-of-function model was ascribed for certain BRCA1 mutants. Our results indicate that complex genetic alterations are operational at the BRCA1 and BRCA2 loci in tumors from genetically predisposed individuals.

Mapping the amplification of EIF3S3 in breast and prostate cancer.

Gain of chromosome arm 8q is a frequent genetic alteration in breast and prostate cancer. Two amplified subregions, 8q21 and 8q23-24, have been identified with comparative genomic hybridization (CGH). We have recently demonstrated that the EIF3S3 (eIF3-p40) gene, located at 8q23, is often amplified and overexpressed in both breast and prostate cancer. Here, we used fluorescence in situ hybridization (FISH) to map the amplified region around EIF3S3 in primary breast cancers and cell lines. The size of the common highly amplified region was about 2.5 Mb between the markers D8S1668 and WI-7959. Next, we analyzed the expression of all expressed sequence tags (ESTs) located within and near this region by RNA slot blot hybridization. In addition to EIF3S3, three anonymous ESTs and EXT1 were found to be highly expressed in cancer cell lines with the amplification at 8q23-q24. However, the anonymous ESTs were located outside the minimal highly amplified region and EXT1 was overexpressed only in one of the cancer cell lines with 8q amplification. Since EIF3S3 was the only consistently overexpressed gene located in the minimal highly amplified region, it is the strongest candidate target gene for 8q23-q24 amplification.

Cyclin D1 expression in astrocytomas is associated with cell proliferation activity and patient prognosis.

An important positive regulator of the cell cycle, cyclin D1, is often amplified and overexpressed in malignancies. Cyclin D1 aberrations were analysed in grade II-IV astrocytomas by fluorescence in situ hybridization (FISH), mRNA in situ hybridization and immunohistochemistry. Proliferation activity was determined by Ki-67(MIB-1) immunolabelling and mitotic counting. High cyclin D1 expression was observed in grade IV astrocytomas (grades II-III versus grade IV; mRNA expression: p<0.001; immunoexpression: p=0.013), and correlated with poor patient survival (p<0.001, n=46). Upregulated cyclin D1 expression was also closely associated with poor patient prognosis in grade II-III astrocytomas (p<0.001, n=30). Cyclin D1 gene was not found to be amplified (n=7). Cell proliferation activity was significantly increased in tumours exhibiting high cyclin D1 mRNA levels (Ki-67(MIB-1): p<0.001; mitotic count: p<0.001) and high cyclin D1 protein expression (Ki-67(MIB-1): p=0.002; mitotic count: p=0.012). These results indicate that increased production of cyclin D1 is closely associated with high cell proliferation activity and aggressive behaviour in diffusely infiltrating astrocytomas.

Amplification and overexpression of p40 subunit of eukaryotic translation initiation factor 3 in breast and prostate cancer.

Amplification at the long arm of chromosome 8 occurs in a large fraction of breast and prostate cancers. To clone the target genes for this amplification, we used suppression subtraction hybridization to identify overexpressed genes in the breast cancer cell line SK-Br-3, which harbors amplification at 8q (8q21 and 8q23-q24). A differentially expressed gene identified by SSH, the p40 subunit of eukaryotic translation initiation factor 3 (eIF3), was localized to 8q23 and found to be highly amplified and overexpressed in the breast and prostate cancer cell lines studied. High-level amplification of eIF3-p40 was found in 30% of hormone-refractory prostate tumors and in 18% of untreated primary breast tumors. In the vast majority of the cases, p40 and c-myc were amplified with equal copy numbers. Tumors with higher copy numbers of p40 than c-myc were also found. Expression of p40 mRNA was analyzed with in situ hybridization. The amplification of eIF3-p40 gene was associated with overexpression of its mRNA, as expected for a functional target gene of the amplification. These results imply that genomic aberrations of translation initiation factors, such as eIF3-p40, may contribute to the pathogenesis of breast and prostate cancer.

Molecular cytogenetic mapping of 24 CEPH YACs and 24 gene-specific large insert probes to chromosome 17.

Defining boundaries of chromosomal rearrangements at the molecular level would benefit from landmarks that link the cytogenetic map to physical, genetic, and transcript maps, as well as from large-insert FISH probes for such loci to detect numerical and structural rearrangements in metaphase or interphase cells. Here, we determined the locations of 24 genetically mapped CEPH-Mega YACs along the FLpter scale (fractional length from p-telomere) by quantitative fluorescence in situ hybridization analysis. This generated a set of cytogenetically mapped probes for chromosome 17 with an average spacing of about 5 cM. We then developed large-insert YAC, BAC, PAC, or P1 clones to the following 24 known genes, and determined refined map locations along the same FLpter scale: pter-TP53-TOP3-cen-TNFAIP1-ERBB2-TOP2A- BRCA1-TCF11-NME1-HLF-ZNF147/CL N80-BCL5/MPO/SFRS1-TBX2-PECAM1-DDX5/ PRKCA-ICAM2-GH1/PRKAR1A-GRB2-CDK3 /FKHL13-qter. Taken together, these 48 cytogenetically mapped large-insert probes provide tools for the molecular analysis of chromosome 17 rearrangements, such as mapping amplification, deletion, and translocation breakpoints in this chromosome, in cancer and other diseases.

Genetic alterations in hormone-refractory recurrent prostate carcinomas.

To study the genetic basis of tumor progression, we have screened 37 hormone-refractory prostate carcinomas for genetic changes by comparative genomic hybridization (CGH). All recurrent tumors showed genetic aberrations, with a mean total number of changes per tumor of 11.4 (range, 3 to 23). The most common genetic aberrations were losses of 8p (72.5%), 13q (50%), 1p (50%), 22 (45%), 19 (45%), 10q (42.5%), and 16q (42.5%) and gains of 8q (72.5%), 7q (40%), Xq (32.5%), and 18q (32.5%). The CGH results were further validated with fluorescence in situ hybridization (FISH) using probes for pericentromeric regions of chromosomes 7, 8, and 18 as well as probes for caveolin (7q31), c-myc (8q24), and bcl-2 (18q21.3). In addition, the samples had previously been analyzed for androgen receptor gene copy number. CGH and FISH results were concordant in 78% of cases. Seventeen of twenty-two tumors showed an increased copy number of c-myc by FISH. However, only 5 of 17 (29%) of the cases showed high-level (more than threefold) amplification. Both CGH and FISH findings suggested that in most of the cases 8q gain involves the whole q-arm of the chromosome. Four of seventeen (24%) cases showed increased copy number of bcl-2 by FISH; however, no high-level amplifications were found. To evaluate the clonal relationship of the primary and recurrent tumors, six primary-recurrent tumor pairs from the same patients were studied by CGH. In three of six cases (50%), the recurrent tumor had more than one-half of the aberrations found in the corresponding primary tumor, indicating a close clonal relationship. In the rest of the cases, such a linear clonal relationship was less evident. Altogether, these results suggest that recurrent prostate carcinomas are genetically unstable. The resulting heterogeneity may well underlie the poor responsiveness of hormone-refractory tumors to treatment.

Genetic aberrations in hypodiploid breast cancer: frequent loss of chromosome 4 and amplification of cyclin D1 oncogene.

The evolution of somatic genetic aberrations in breast cancer has remained poorly understood. The most common chromosomal abnormality is hyperdiploidy, which is thought to arise via a transient hypodiploid state. However, hypodiploidy persists in 1 to 2% of breast tumors, which are characterized by a poor prognosis. We studied the genetic aberrations in 15 flow cytometrically hypodiploid breast cancers by comparative genomic hybridization (CGH) and fluorescence in situ hybridization (FISH). Surprisingly, numerous copy number gains were detected in addition to the copy number losses. The number of gains per tumor was 4.3 +/- 3.2 and that of losses was 4.5 +/- 3.3 (mean +/- SD), which is similar to that previously observed in hyperdiploid breast cancers. Gains at chromosomes or chromosomal regions at 11q13, 1q, 19, and 16p and losses of 2q, 4, 6q, 9p, 13, and 18 were most commonly observed. Compared with unselected breast carcinomas, hypodiploid tumors showed certain differences. Loss of chromosome 4 (53%) and gain of 11q13 (60%) were significantly more common in hypodiploid tumors. The gain at 11q13 was found by FISH to harbor amplification of the Cyclin D1 oncogene, which is therefore three to four times more common in hypodiploid than in unselected breast cancers (15 to 20%). Structural chromosomal aberrations (such as Cyclin D1 amplification) were present both in diploid and hypodiploid tumor cell populations, as assessed by FISH and CGH after flow cytometric sorting. Together these results indicate that hypodiploid tumors form a distinct genetic entity of invasive breast cancer, although they probably share a common genetic evolution pathway where structural chromosomal aberrations precede gross DNA ploidy changes.

Genetic alterations in prostate cancer cell lines detected by comparative genomic hybridization.

Recent studies have identified several chromosomal regions that are altered in prostate cancer. However, the specific genes affected are, in most of the cases, not known. Cancer cell lines could provide a valuable resource for cloning of genes that are commonly affected in cancer. The first step in the identification of such genes is the detection of chromosomal aberrations. Here, we have used comparative genomic hybridization (CGH) to screen for genetic alterations in four prostate cancer cell lines, LNCaP, DU145, PC-3, and TSU-Pr1. The analysis showed that, except for the LNCaP, these cell lines contained many genetic changes (> or = 10 per cell line), suggesting that they resemble genetically more closely hormone-refractory or metastatic than primary prostate carcinomas. All the chromosomal regions that have been implicated in prostate cancer were altered in at least one of the cell lines. The most common genetic changes were gain at 11q and losses at 6q, 9p, and 13q, each present in at least three cell lines. Identification of genetic aberrations by CGH in these cell lines should facilitate the choice of individual cell lines for cloning of genes that are involved in the development and progression of prostate cancer.